INDUCTION OF METALLOTHIONEIN WITH CADMIUM CHLORIDE IN A ECONOMICALLY IMPORTANT FRESHWATER FISH-GRASS CARP, CTENOPHARYNGODON IDELLA (VALENCIENNES, 1844)

Authors

  • SURESH A Department of Zoology,Presidency College (Autonomous), Chennai - 600 005.
  • MEENA B Department of Zoology,Presidency College (Autonomous), Chennai - 600 005.
  • SUMIT ROSE Department of Zoology,Presidency College (Autonomous), Chennai - 600 005.
  • MANI R Department of Biotechnology,St.Peter's University, Avadi, Chennai - 54.

Abstract

Objectives: Metallothioneins (MTs) have been widely considered for their potential use as a specific biomarkers to reflect the existence of heavy
metal pollution, because their induction has been observed to be obviously elevated after heavy metal exposure in a large number aquatic
organisms. However, relatively fewer efforts have been made to study the related effects of MT in fish species, such as Ctenopharyngodon idella
(C. idella), a globally important aquaculture species. The objective of this study was to determine the cadmium (Cd) levels and MT induction in
muscle, gill, kidney, and liver in C. idella during acute Cd exposure, to study the relationship between tissue-specific Cd accumulation and MT
induction.
Methods: Cd accumulation and MT induction levels was determined according to the methods of Ma et al., 2007. Cd concentration was determined
using an atomic absorption spectrophotometer (Perkin Elmer Optima-5300 DV).
Results: The MT induction levels were found in an increasing order of liver>kidney>gill >muscle. A positive correlation was shown between MT
induction and Cd accumulation. The accumulation of Cd levels in all tissues is distinct by time-dependent and dose-dependent.
Conclusion: These results suggest that MT in the liver played an important role to detoxify high quantities of Cd. Cd accumulation showed a positive
correlation with MT induction in all the tissues studied. Hence, the present investigation marks that MT levels can be considered as a biomarker for
acute waterborne Cd.
Keywords: Heavy metals, Atomic absorption spectrophotometry, Biomarker protein, Metallothionein, Ctenopharyngodon idella.

Downloads

Download data is not yet available.

References

Jabeen G. Studies on fish species specific metals bio-accumulation

patterns in relation to water, sediments and plankton in the river Ravi.

Ph.D. Thesis. Department of Zoology and Fisheries University of

Agriculture Faisalabad; 2012.

Azmat H, Javed M, Jabeen G. Acute toxicity of aluminium to the

fish (Catla catla, Labeo rohita and Cirrhina mrigala). Pak Vet

;31(1):85-7.

Jones MM, Cherian C. Cadmium a unique metal. Toxicol

;62(1):1-25.

Otchere FA. Heavy metals concentrations and burden in the bivalves

(Anadara (Senilia) senilis, Crassostrea tulipa and Pernaperna) from

lagoons in Ghana: Model to describe mechanism of accumulation/

excretion. Afr J Biotech 2003;2(9):280-7.

Amisah S, Adjei-Boateng D, Obirikorang KA, Quagrainie K. Effects of

clam size on heavy metal accumulation in whole soft tissues of Galatea

paradoxa (Born, 1778) from the Volta estuary, Ghana. Int J Fish Aquat

;1:014–21.

Ahmed MS, Aslam Y, Khan WA. Absorption and bioaccumulation of

water-borne inorganic mercury (Hg) in the fingerlings of grass carp,

Ctenopharyngodon idella. J Anim Plant Sci 2011;21(2):176-81.

Roberts JR. Metal toxicity in children. Training Manual on Pediatric

Environmental Health: Putting it into Practice. Emeryville, CA:

Children’s Environmental Health Network; 1999.

Järup L. Hazards of heavy metal contamination. Br Med Bull

;68:167-82.

Bryan GW, Langston WJ. Bioavailability, accumulation and effects of

heavy metals in sediments with special reference to United Kingdom

estuaries: A review. Environ Pollut 1992;76(2):89-131.

Atrno K, Volker R, Yona C. Cadmium binding by fractions of dissolved

organic matter and humic substances from municipal solid waste

compost. J Environ Qual 2002:31(6):1885-92.

Audry S, Schäfer J, Blanc G, Jouanneau JM. 50-year sedimentary

record of heavy metal pollution (Cd, Zn, Cu, Pb) in the Lot River

reservoirs (France). Environ Pollut 2004;132(3):413-26.

Chrastný V, Komárek M, Tlustos P, Svehla J. Effects of flooding on lead

and cadmium speciation in sediments from a drinking water reservoir.

Environ Monit Assess 2006;118(1-3):113-23.

Waisberg M, Joseph P, Hale B, Beyersmann D. Molecular and

cellular mechanisms of cadmium carcinogenesis. Toxicology

;192(2-3):95-117.

Margoshes M, Vallee BL. A cadmium protein from equine imaging

hyperintensity in Alzheimer’s disease: Correlation with kidney cortex.

J Am Chem Soc 1957;79:4813-4.

Syring RA, Brouwer TH, Brouwer M. Cloning and sequencing of

cDNAs encoding for a novel copper-specific metallothionein and two

cadmium-inducible metallothioneins from the blue crab Callinectes

sapidus. Comp Biochem Physiol C 2000;125(3):325-32.

Kägi JH, Schäffer A. Biochemistry of metallothionein. Biochemistry

;27(23):8509-15.

Sorensen EM. Cadmium. Metal Poisoning in Fish. Boston: CRC Press;

p. 175-234.

Ma W, Wang L, He Y, Yan Y. Tissue-specific cadmium and

metallothionein levels in Sinopotamon henanense. Environ Toxicol

;23(3):393-400.

Pedersen KL, Pedersen SN, Højrup P, Andersen JS, Roepstorff P,

Knudsen J, et al. Purification and characterization of a cadmiuminduced

metallothionein

from

the

shore

crab

Carcinus

maenas

(L.).

Biochem

J 1994;297:609-14.

Jezierska B, Witeska M. Metal Toxicity to Fish. Siedlce, Poland:

University of Podlasie; 2001. p. 51-68.

Kay J, Thomas DG, Brown MW, Cryer A, Shurben D, Solbe JF,

et al. Cadmium accumulation and protein binding patterns in tissues

of the rainbow trout, Salmo gairdneri. Environ Health Perspect

;65:133-9.

Giles MA. Accumulation of cadmium by rainbow trout, Salmo gairdneri,

during extended exposure. Can J Fish Aquat Sci 1988;45:1045-53.

Glynn AW, Olsson PE. Cadmium turnover in minnows (Phoxinus

phoxinus) preexposed to water born cadmium. Environ Toxicol Chem

;10(3):338-94.

Gill TS, Epple A. Stress-related changes in the hematological profile

of the American eel (Anguilla rostrata). Ecotoxicol Environ Saf

;25(2):227-35.

Martinez M, Torreblanca A, Ramo JD, Pastor A, Diaz-Mayans J.

Cadmium induced metallothionein in hepatopancreas of Procambarus

clarkii: Quantification by a silver-saturation method. Comp Biochem

Physiol C 1993;105(2):263-7.

Wu JP, Chen HC. Metallothionein induction and heavy metal

accumulation in white shrimp Litopenaeus vannamei exposed to

cadmium and zinc. Comp Biochem Physiol C 2005;140(3-4):383-94.

Asian J Pharm Clin Res, Vol 8, Issue 5, 2015, 132-137

Suresh et al.

Hogstrand C, Haux C. Binding and detoxification of heavy metals in

lower vertebrates with reference to metallothionein. Comp Biochem

Physiol C 1991;100(1-2):137-41.

Kovarova J, Kizek R, Adam V, Harustiakova D, Celechovska O,

Svobodova Z. Effect of cadmium chloride on metallothionein levels in

carp. Sensors (Basel) 2009;9(6):4789-803.

Berntssen MH, Aspholm OO, Hylland K, Wendelaar-Bonga SE,

Lundebye AK. Tissue metallothionein, apoptosis and cell proliferation

responses in Atlantic salmon (Salmo salar L.) parr fed elevated dietary

cadmium. Comp Biochem Physiol C 2001;128(3):299-310.

Huang ZY, Zhang Q, Chen J, Zhuang ZX, Wang XR. Bioaccumulation

of metals and induction of metallothioneins in selected tissues

of common carp (Cyprinus carpio). Appl Organomet Chem

;21(2):101-7.

Published

01-09-2015

How to Cite

A, S., M. B, S. ROSE, and M. R. “INDUCTION OF METALLOTHIONEIN WITH CADMIUM CHLORIDE IN A ECONOMICALLY IMPORTANT FRESHWATER FISH-GRASS CARP, CTENOPHARYNGODON IDELLA (VALENCIENNES, 1844)”. Asian Journal of Pharmaceutical and Clinical Research, vol. 8, no. 5, Sept. 2015, pp. 276-81, https://mail.innovareacademics.in/journals/index.php/ajpcr/article/view/6941.

Issue

Vol 8 Issue 5 (September - October) 2015

Section

Original Article(s)

The publication is licensed under CC By and is open access. Copyright is with author and allowed to retain publishing rights without restrictions.